pre-algebra and algebra instruction and assessments
TRANSCRIPT
Pre-Algebra and Algebra Instruction and Assessments
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in partnership with the Florida Center for Reading Research at Florida State
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Evaluation, and Statistics at the University of Houston; and the Vaughn
Gross Center for Reading and Language Arts at the University of Texas at Austin.
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2006
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Algebra and NCTM Focal Points
Overview of the Focal Points
• PreK through grade 8• Important math topics / content in
mathematics by grade• Cohesive clusters of related ideas /
concepts / skills that form foundation for higher level mathematics– NOT discrete topics that teachers teach
and students master
Algebra Learning Expectations Across States: Grade 4
412Virginia
453Georgia
263North Carolina
566New Jersey
560Michigan
486Ohio
8910Florida
565New York
324Texas
437California
TotalAlgebraState
Algebra in Prekindergarten
• Patterns: recognize and duplicate sequential patterns
Algebra in Kindergarten
• Identify, duplicate, and extend:– Number patterns
– Sequential and growing patterns with shapes
• Preparation for creating rules that describe relationships– E.g., each new pattern grows by one
Algebra in Grade 1
• Understand connection between counting and operations of addition and subtraction (e.g., adding two is the same as “counting on” two)
• Use properties of commutativity and associativity to add whole numbers
• Begin to relate addition and subtraction as inverse operations
Algebra in Grade 2
• Use number patterns to extend understanding of properties of numbers and operations– E.g., skip counting builds foundation of
understanding multiples and factors
Algebra in Grade 3
• Understand meaning of multiplication and division (equal “jumps,” equal-sized groups, area models)
• Creation and analysis of patterns and relationships involving multiplication and division
Algebra in Grade 4
• Students understand number patterns involving all operations and nonnumeric growing or repeating patterns– Can use rules to describe a sequence of
numbers or objects
– E.g., 2, 4, 8, 16, 32
Algebra in Grade 5
• Use patterns, models, relationships to write and solve simple equations and inequalitiesE.g., 2, 4, 8, 16, __ = 16*2 = 32.
• Create graphs of simple equationsx: 1 2 3 4 5y: 2 4 8 16 32
Algebra in Grade 6• Algebra is a Curriculum Focal Point for
the first time on its own• Write and evaluate mathematical
expressions; use expressions and formulas to solve problems.
• Expressions in different forms can be equivalent
• Understand that variables represent numbers whose precise values are not yet specified
Algebra in Grade 7
• Algebra is in all 3 Curriculum Focal Points
Algebra in Grade 8
• Analyzing and representing linear functions, solving linear equations, and systems of linear equations
• Also beginning to explore nonlinear functions
Algebra Instruction
Algebra and the Elementary Grades
• Algebra has often been characterized as developmentally constrained due to its inherent abstractness (e.g., Kieran, 1981, 1985; Vergnaud, 1985)
• Research in the former Soviet Union suggested that young children could generalize arithmetic, moving from particular to generalized numbers, learning to use variables and covariation in word problems, and focusing on the concept of function (Davydov, 1991, Bodanskii, 1991)
Algebra and the Elementary Grades
• Recent research suggests that inappropriate instruction may have had a decisive role in the poor results from early studies of algebraic reasoning among adolescents in the U.S. (Booth, 1988; Schliemann & Carraher, 2002).
Critical Topics for Teaching and Learning Algebra
1. Variables and constants2. Decomposing and setting up word
problems3. Symbolic manipulation4. Functions5. Inductive reasoning and mathematical
inductionMilgram (2005)
Connecting Arithmetic to Algebra
Numerical Expression Algebraic Expression
7 + 3 n + 3
variable constant
Here is how you read algebraic expressions
sum n + 3 “n plus 3”
product 3 x n or 3n “3 times n”
difference n – 3 “n less 3”
quotient n÷3 “n divided by 3”
In the Dog House
J. Porzio (2006)
Moving from Expressions to Equations
• Problem: The left pan of a set of scales contains 5 identical boxes of noodles, and the right pan contains 3 identical boxes and two 2-kg weights. The scales are balanced. How much does each box weigh?
2Kg2Kg
5x = 3x + 4
Equation: An equality with a variable.Root: Each value of the variable that makes the statement a true equality.
J. Porzio (2006)
J. Porzio (2006)
5 + t truckloadsEach truckload contained 3 tons of sandThe total amount of sand delivered is 3 X (5 + t)
3 (5 + t) is an expression with a variable
If t is 2, than 3 X (5 + 2) = 21If t is 5, than 3 X (5 + 5) = 30
Milgram, 2005
Variables and Properties
• A variable represents a number–even though its value may not be given.
• Expressions with variables satisfy all the properties of the number system, such as the commutative, associative, and distributive properties.
The Real Numbers
Defines Division
Defines Addition,Subtraction, andMultiplication
5 + 2 = 2 + 5
Commutative Property of Addition
5 + t = t + 5
Commutative Property of Addition
3 X 7 = 7 X 3
Commutative Property of Multiplication
3 X t = t X 3
Commutative Property of Multiplication
3 X 7 X 2 = 7 X 2 X 3
Associative Property of Multiplication
5 X 3 X t = t X 3 X 5
Associative Property of Multiplication
3 X (5 + 2) = 3 X 5 + 3 X 2
Distributive Property of Multiplication
3 X (5 + t) = 3 X 5 + 3 X t
Distributive Property of Multiplication
3 + 5 + 2 = 5 + 2 + 3
Associative Property of Addition
3 + 5 + t = 5 + t + 3
Associative Property of Addition
271530075423618153 X 5 + 3 X t
271530075423618153 X (5 + t)
90095209710t
Key Definitions: Expressions with More than One Variable
1. Solution of an equation: A value (or an ordered pair of values) that satisfies the equation
2. Equivalent equations: Equations that have the same solution set
3. Linear equation: An equation equivalent to one of the form ax + by = c with a2 + b2 not equal to 0
4. Function: A rule connecting two sets that assigns to each element of one set (or input) one and only one element of the second set (or output)
5. Graph of an equation in two variables: Points in the plane whose coordinates satisfy the equation
6. Sequence: A function from the positive integers to the real numbers.
Expressions involving Two or More Variables…
• Adhere to the same commutative, associative, and distributive properties:
x(4x3 + 2y3) = x . 4 . x3 + x . 2 . y3
= 4 . x . x3 + 2 . x . y3
= 4x4 + 2xy3
A Historical Statement on Translating Word Problems
• In solving a word problem by setting up equations, the student translates a real situation into mathematical terms: he has an opportunity to experience that mathematical concepts may be related to realities, but such relations must be carefully worked out. Here is the first opportunity afforded by the curriculum for this basic experience.
G. Polya, Mathematical Discovery, Volume 1, P. 59
Process for Translating Word Problems to Algebra Problems1. Students verbally read and explain what an
expression/equation means,2. Students formulate a verbal instruction as an
algebraic expression,3. Students translate components of word problems
into mathematical expressions,4. Students construct word problems associated with a
particular algebraic expression5. Students define variables, and6. Students explicitly solve problems
Introduction to Functions
Rulef(x) = x+4
Input 2
Output6
Functions Can Be Introduced Early without Formal Definitions
Cfunction
Definition
Examples Counter Examples
Synonyms
A rule between two sets such that there is a unique element in the second set assigned to each in the first set
rule of correspondence
f(x) = x + 4
{(1, 2), (3, 2), (5, 1)}
3y + 5x
{(1, 2), (1, 3), (4, 0)}
Mathematics Progress Monitoring in Secondary
Grades
Monitoring Student Progress
• The process of collecting and evaluating data to make decisions about the adequacy of student progress toward a goal and/or responding to instruction or interventions
• Evaluation of student rate of change (slope) as compared to the slope of anticipated progress
• Requires:– Technically sound measures– Multiple forms of the same measure– Assessment systems that are sensitive to student growth– Standardized administration procedures– Frequent measurement (occurs at least monthly)
Adapted from NCSPM
Research Supports the Use of Progress Monitoring
• Progress monitoring data produce accurate, meaningful information about students’ academic levels and their rates of improvement
• Progress monitoring data are sensitive to student improvement
• Performance on progress monitoring measures corresponds well to performance on high-stakes tests
• When teachers use progress monitoring data to inform their instructional decisions, students make greater learning gains
Process of Progress Monitoring
• Progress monitoring is a data-based instructional decision making tool
• Steps for using data:– Gather baseline performance data– Set instructional goals– Provide targeted instruction– Monitor progress toward goal– Adjust goal upward or modify instruction as
needed
Adapted from NCSPM
Example of Progress Monitoring Data
0
10
20
30
40
50
60
70
Sep Oct Nov Dec Jan Feb Mar Apr May
Donald Ross Computation 4
DIGITS
G38
Features of Progress Monitoring Systems
• Data are collected and evaluated frequently– Schedule is determined by goal and current level of student
performance – Typically ranges from 2 times per week to monthly
• Teachers may choose to monitor progress of all students in class
• Typically, students at-risk of failure are assessed until they reach proficiency
• Data-based decision rules are applied to graphed data to determine when goals should be raised or instruction should be modified
Measuring Secondary Students’ Progress in
Mathematics• Development of progress monitoring
measures for secondary grades (especially beyond general math) is in its infancy
• Project AAIMS is developing and validating measures for pre-algebra and first year algebra
• Algebra measures have been created using both the robust-indicators and the curriculum-sampling methods
Algebra Progress Monitoring Research Results
• Project AAIMS evaluates technical adequacy and teachers’ use of algebra measures
• Reliability, criterion validity, and sensitivity to growth over time is documented for the Basic Skills, Algebra Foundations, and Content Analysis-Multiple Choice measures
• Less data on the Translations measure due to mismatch with existing curriculum materials in participating school districts
• Research is on-going to continue refinement of the measures
• Basic Skills• Algebra Foundations• Translations• Content-Analysis-Multiple Choice
Examples of Algebra Progress Monitoring Measures
Basic Skills in Algebra
• Robust indicator of pre-algebra/algebra proficiency• Problems include:
– Solving basic “fact” equations– Applying the distributive property– Working with integers– Combining like terms– Simplifying expressions – Applying proportional reasoning
• Timed administration• Constructed-response items• Scored by counting number of problems correct
Basic SkillsAl ge b ra P r o b e A - 3 1 P age 1
Sol v e: 9 + a = 15 a =
Sol v e: 10 – 6 = g g =
E v al ua te : 12 + ( – 8) + 3
Si m p l if y : 9 – 4d + 2 + 7d
Si m p l if y : 2 x + 4 + 3x + 5
Si m p l if y : 5( b – 3) – b
Sol v e: 12 – e = 4 e =
Sol v e: q • 5 = 30 q =
Si m p l if y : 4(3 + s ) – 7
E v al ua te : 8 – ( – 6) – 4
Si m p l i f y : b + b + 2 b
Si m p l if y : 2 + w ( w – 5)
Sol v e:
18
12
6=b
b =
Sol v e: 1 foot =12 i n c hes 5 fe e t = _ _ _ _ in c h es
Si m p l if y : 7 – 3( f – 2 )
Si m p l if y : 4 – 7b + 5 (b – 1)
E v al ua te : – 5 + ( – 4) – 1
Si m p l if y : s + 2 s – 4 s
Sol v e: 63 ÷ c = 9 c =
S ol v e: x + 4 = 7 x =
Si m p l if y : 2( s – 1) + 4 + 5 s
Si m p l if y : – 5( q + 3) + 9
Si m p l if y : 8 m – 9( m + 2)
E v al ua te : 9 + ( – 3) – 8
Algebra Foundations
• Robust indicator of pre-algebra/algebra proficiency• Problems include:
– Writing and evaluating variables and expressions– Computing expression (integers, exponents, and order of
operations)– Graphing expressions and linear equations– Solving 1-step equations and simplifying expressions– Identifying and extending patterns in data tables
• Timed administration• Constructed-response items• Scored by counting number of problems correct
Algebra Foundations
Content Analysis
• Curriculum sampling approach to algebra proficiency
• Problems are sampled from core concepts in the first 2/3 of a traditional Algebra 1 textbook
• Multiple-choice items with partial credit• Scored by counting number of points earned
– Up to 3 points per problem awarded using a scoring rubric
– -1 point penalty for circling an incorrect answer without showing any work (guessing)
Evaluate b2 − a2 when a = 4 and b = 5
a) 21 b) 1 c) 11 d) 9
Rewrite this expression without parentheses: (-5) (4 – y)
a) 9 - y b) -20 + 5y c) -1 – 5y d) -20 – 5y
Solve: 2t – 5 = 7
a) 1
2
b) 6 c) 1 d) 2
Solve: y3 = 4
a) -10 b) 7 c) 4
3
d) 12
Which line on the graph is y = 2?
a) Line A b) Line B c) Line C
d) Line D
Which line on the graph is y + 2x = 4 ?
a) Line A b) Line B c) Line C
d) Line D
Write the equation in slope- intercept form: m = ( 1
2) b = 3
a) y = 2x + 3 b) y = 3x + 1
2
c) x = 1
2y – 3
d) y = 1
2x + 3
Rewrite this equation in standard form using integer coefficients. -4y + 1
2x = 2
a) -8y + 2x = 4 b) x – 8y = 4 c) y = 4x + 8 d) 4y – 2x = 4
A B
C
D
B
C
D
A
Content Analysis - Multiple Choice
Translations
• Robust indicator of pre-algebra/algebra proficiency• Problems include:
– Tasks drawn from Connected Mathematics Project (CMP) Curriculum
– Translate representations for relationships between two variables
• Data tables• Graphs • Equations • Story scenarios
• Timed administration• Scored by counting number of problems correct and
subtracting number of problems incorrect
Translations
Summary: Uses of Progress Monitoring Data
• Estimate rates of student improvement
• Describe student response to instructional program
• Inform teachers’ instructional decision making• Aid teachers in targeting areas/skills that
need remediation
• Help teachers build potentially more effective programs for particular students
References
Text Material:• Milgram, J. (2005). XXXX• Porzio, J. (2006). XXXXWebsites:• Project AAIMS Web site
www.ci.hs.iastate.edu/aaims
Additional Resources
National Centers• National Center on Student Progress
Monitoring (NCSPM): http://www.studentprogress.org
• Research Institute on Progress Monitoring (RIPM): http://www.progressmonitoring.org
Pre-Algebra and Algebra Instruction and Assessments